Connection length: Difference between revisions
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:<math>L = 2 \pi r \frac{B_\phi}{B_\theta} = 2 \pi R q</math> | :<math>L = 2 \pi r \frac{B_\phi}{B_\theta} = 2 \pi R q</math> | ||
where q is the [[ | where q is the [[Rotational transform|safety factor]], approximated by | ||
''q = r B<sub>φ</sub> / R B<sub>θ</sub>''. | ''q = r B<sub>φ</sub> / R B<sub>θ</sub>''. | ||
Revision as of 16:23, 30 July 2010
The connection length is understood to be the distance between two points, measured along a magnetic field line passing through these points.
In the fusion context, a distinction is made between closed field lines (inside the Last Closed Flux Surface) and open field lines (outside).
Closed field lines
Inside the Last Closed Flux Surface, the connection length is commonly defined as the length, measured along the magnetic field, to complete a poloidal turn.
In a circular tokamak, the poloidal circumference is 2πr. The connection length is L = 2πr/sin(α), where α is the pitch angle of the field line, namely tan(α) = Bθ/Bφ. Assuming Bφ >> Bθ, one has sin(α) ∼ tan(α), so that [1]
where q is the safety factor, approximated by q = r Bφ / R Bθ.
Open field lines
Outside Last Closed Flux Surface, the connection length associated with a given point is defined as the shortest distance from that point to any material surface measured along the field line through that point.
References
- ↑ K. Miyamoto, Plasma Physics and Controlled Nuclear Fusion, Springer-Verlag (2005) ISBN 3540242171